KR100736500B1 - Communication system of VSB digital TV - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital communication system, and more particularly, to a VBS communication system of a digital TV that modulates the signal in a VSB (Versatial Side Band) scheme and transmits the same.

According to another aspect of the present invention, there is provided a VBS communication system for digital TV, comprising: reed-solomon encoding means for encoding additional data to be sent through a first path; Interleaving means for performing an interleaving process on the encoded additional data; Repeating encoding means for iteratively encoding the input 1 byte into 2 bytes with respect to the interleaved additional data; A header adder for adding an MPEG header to the repeated coded additional data; A multiplexer for multiplexing the additional data added with the header and MPEG data input through a second path; And an 8T-VSB transmission system for modulating and transmitting the multiplexed data with respect to the data input through the first and second paths in a VSB transmission method.

Supplementary Data, Repeated Encoder, VSB, Digital Communication System

Description

VBS communication system of digital TV {Communication system of VSB digital TV}

1 is a view showing the configuration of a conventional VSB transmission system

2 is a signal constellation diagram of additional data according to the present invention.

3 is a diagram illustrating a VBS communication system of a digital TV including additional data according to the present invention.

4 is a diagram illustrating a data frame structure of a VSB transmission system according to the present invention.

5 is a diagram for multiplexing MPEG data and additional data.

6 is a block diagram of data in the memory of the repeater.

7 is a diagram illustrating data interleaving for additional data.

8 shows a trellis encoder and a precoder

9 is a diagram illustrating a process of encoding an additional data (N = 164).

10 is a diagram illustrating a process of encoding an additional data (N = 82).

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital communication system, and more particularly, to a VBS communication system of a digital TV that modulates the signal in a VSB (Versatial Side Band) scheme and transmits the same.

In the United States, ATSC 8T-VSB transmission system was adopted as a standard in 1995 for terrestrial digital broadcasting, and broadcasted since the second half of 1998.In Korea, ATSC 8T-VSB transmission system, which is identical to the US method, was adopted as a standard in May 1995. Experimental broadcasting was started, and on August 31, 2000, the test broadcasting system was switched.

1 shows a conventional ATSC 8T-VSB transmission system. The data randomizer randomizes the input MPEG video / audio data, the Reed-Solomon encoder adds 20 bytes of parity code by reed-solomon encoding the data, the data interleaver interleaves the data, and the trellis encoder The data is converted from bytes to symbols and trellis encoded. The mux constructs a symbol sequence by muxing the data sequence and the synchronization signals, the pilot inserter adds a pilot signal to the symbol sequence, the VSB modulator modulates the symbol sequence into an 8 VSB signal of an intermediate frequency band, and an RF converter an intermediate frequency band signal. Is converted into an RF band signal and transmitted through an antenna. USP5636251, USP5629958, and USP5600677, which are filed by Zenith in the US and registered in the US, are related to the conventional VSB transmission system.

      The 8T-VSB transmission system, adopted as a digital broadcasting standard in North America and Korea, is a system developed for transmission of MPEG video / audio data. However, with the rapid development of digital signal processing technology and the widespread use of the Internet, digital home appliances, computers, and the Internet are being integrated into one big framework. Therefore, in order to meet various needs of users, it is necessary to develop a system capable of transmitting various additional data in addition to video / audio data through a digital broadcasting channel.

Some users of supplementary data broadcasting are expected to use supplementary data broadcasting by using PC card or portable device equipped with simple indoor antenna. In the room, signal strength is greatly reduced by wall blocking and influence of proximity moving body. Due to the effects of ghosts and noise caused by reflected waves, broadcast reception performance may deteriorate. However, unlike general video / audio data, the additional data transmission should have a lower error rate. In the case of video / audio data, errors that the human eye and ears cannot detect are not a problem, while in the case of additional data (eg program execution file, stock information, etc.), a bit error may cause serious problems. It can cause problems. therefore There is a need to develop a system that is more resistant to ghosting and noise in the channel.

The transmission of additional data will usually be done in a time division manner over the same channel as the MPEG video / sound. Since the beginning of digital broadcasting, however, ATSC VSB digital broadcasting receivers that receive only MPEG video / audio have been widely used in the market. Therefore, additional data transmitted on the same channel as MPEG video / audio should not adversely affect the existing ATSC VSB-only receivers that have been widely used in the market. Such a situation is defined as ATSC VSB compatible, and the additional data broadcasting system should be compatible with the ATSC VSB system.

In addition, in a poor channel environment, the reception performance of the conventional ATSC VSB receiving system may be degraded. In other words, the present applicant has previously applied for a related patent to solve such problems (P00-83533, 2000.12.28, P01-3304, 2001.1.19).

 The present invention is to provide a new digital TV VBS communication system suitable for additional data transmission and resistant to noise. In addition, another object of the present invention to provide an additional data transmission system compatible with the existing 8VSB system. It is another object of the present invention to provide another embodiment of the transmission system described in the patent application P00-83533, 2000.12.28 filed by the present applicant.

According to an aspect of the present invention, there is provided a VBS communication system for digital TV, comprising: reed-solomon encoding means for encoding additional data to be sent through a first path; Interleaving means for performing an interleaving process on the encoded additional data; Repeating encoding means for iteratively encoding the input 1 byte into 2 bytes with respect to the interleaved additional data; A header adder for adding an MPEG header to the repeated coded additional data; A multiplexer for multiplexing the additional data added with the header and MPEG data input through a second path; And an 8T-VSB transmission system for modulating and transmitting the multiplexed data with respect to the data input through the first and second paths in a VSB transmission method.
The repeating coder generates and outputs 2 bytes by repeating the input 1 byte. The reason for the repetition code is that the reception performance can be improved by increasing the distance between symbols in the trellis encoder. That is, the distance between symbols increases by transmitting 000,110,001,111 during trellis coding by using the repetition code. The reception performance is improved. In the above, the interleaver may or may not perform an interleaving process on Reed Solomon-coded data. That is, it may be an unnecessary component in the transmission system. The multiplexing unit multiplexes the additional data inputted as the first path and the MPEG stream inputted as the second path in units of segments. In addition, the multiplexing ratio may be different according to the amount of data. It may be multiplexed according to the multiplexing rules described in the previously applied patent (P01-20929,2001.4.18).

In addition, a first feature of the additional data signal format of the present invention for achieving the above object is composed of 3 bytes of MPEG header and 184 bytes of repeated coded data in total of 187 bytes in one segment unit. Some of the 184 bytes, except 3, contain Reed Solomon parity.

First, the VSB signal constellation of the present invention will be described with reference to FIG. As shown in FIG. 2, when additional data is repeatedly transmitted, four symbols (000, 110, 001, 111) are output. That is, in the trellis encoder, eight symbols are conventionally output, but according to the present invention, four symbols are output, thereby reducing the possibility of error as the distance between symbols increases.

      3 illustrates a digital TV's VB communication system including additional data. The first path shows that the broadcasting station performs several encoding processes to transmit additional data to the receiver through a channel (public or cable). First, an error is encoded by a Reed Solomon encoder (R-S encoder) to perform error correction. An interleaving process is performed to improve burst noise performance on the encoded additional data. In this case, the interleaver may be omitted if necessary. The interleaved data is repeatedly encoded so that four symbols can be output by inputting repetitive encoded data to the input terminal of the trellis encoder for the interleaved or Reed Solomon coded additional data. The reason for the encoding is to ensure that the reception can be performed well even in a poor channel environment. The repeated coded data structure will be described later with reference to FIG. 7. The repeated coded additional data is MPEG for compatibility with an existing VSB receiver. After the header is added, it is input to the multiplexer. In addition, broadcast program data (eg, movies, sports, entertainment, dramas, etc.) in the second path is input to the multiplexer through MPEG encoding. The multiplexer (eg, mux) outputs additional data and MPEG data inputted through the first and second paths to a VSB transmission system (eg, 8T-VSB transmission system) according to a control operation (not shown) of the controller. . With respect to the multiplexed data, the VSB transmitting system processes the data and transmits the data to the receiver through the channel in the same manner as the conventional method. As the above example of the Reed-Solomon encoding method for the additional data, the block size N = 184. , payload K = 164, error correction capability T = 10 can be used. At this time, the generation polynomial of the Galois field and the encoder may be the same as the Reed-Solomon encoder of the VSB transmission system. The specifications N, K, and T of this Reed-Solomon encoder can be changed. For example, a code of N = 184, K = 154, T = 15 may be used, and a code of N = 92, K = 82, T = 5 may be used. Instead of the Reed-Solomon code, other codes with good performance may be used.

4 is a diagram showing a data frame and a segment configuration of a VSB transmission system. Each segment or some segments include the additional data described above. One data field consists of 312 data segments and one field sync segment, and each data segment consists of 187 bytes of data (including 3 MPEG headers) and 20 bytes of ATSC Reed-Solomon parity. The three bytes representing the MPEG header above are related to the MPEG decoder. In other words, ISO / IEC 13818-1 specifies the header of MPEG transport packets. Except for the sync byte of 0x47, There is a 3-byte header that defines the PID (Program ID). In the transport section of the MPEG decoder, if the PID of the received packet is not the PID defined by the predetermined table, the packet is discarded. Therefore, the MPEG header inserter for additional data shown in FIG. A three-byte header including a PID that is not included is inserted into the additional data packet. Thus, it can be distinguished from MPEG data input through the second path.

       FIG. 5 is a diagram illustrating an embodiment in which the multiplexer of FIG. 2 multiplexes additional data and MPEG data. Multiplexing of MPEG data and additional data may be performed in units of data segments. Multiplexing is performed in synchronization with the field synchronization signal used for data frame synchronization in the VSB transmission system. The receiver can find and demultiplex MPEG data and additional data in synchronization with the field synchronization signal. The rate and method of multiplexing can be varied, and the information can be informed to the receiver using 92 bits in a reserved area in the field sync signal. In order to enable the receiver to more reliably recover the multiplexed information, the receiver may insert and transmit not only the field synchronization signal but also additional data. 5 is a diagram illustrating an example of multiplexing, in which additional data is multiplexed 1/2 of a total of 312 data segments. This multiplexing rate is determined according to the broadcasting station's circumstances. It may also be multiplexed according to the multiplexing rules described in the patent filed by the present applicant (P01-20929, 2001.4.18).

FIG. 6 is a diagram showing the configuration of data in the memory of the repeater. When one byte is input, as shown in the figure, a repeating bit is inserted to output two bytes. The additionally encoded additional data is encoded by Reed Solomon without interleaving randomizers present in the 8T-VSB transmission system shown in FIG. It does not go through the randomizer shown in FIG. The relationship between the repeated coded additional data and the trellis encoder will be described in detail with reference to FIG.

      7 illustrates an embodiment of an interleaver for additional data. The interleaver shown as an embodiment is a convolutional interleaver, and corresponds to the case where the number of branches B = 46 and the number of bytes M = 4 of the unit memory. The interleaver synchronization can be matched to the field synchronization signal of the VSB transmission system. The values of B and M shown as an example

Other interleavers such as block interleavers may be used instead of convolutional interleavers. In addition, since the existing ATSC transmitter has a data interleaver, the interleaver for additional data may be omitted if there is no need to improve the performance of the burst noise.

     8 shows a trellis encoder and a precoder. When two bits (d1, d0) are input, three bits (c2, c1, c0) are output and converted into one of eight levels by an 8VSB converter. The additional data is input to the trellis encoder without passing through the precoder. Since the output of the interleaver shown in FIG. 7 is a byte unit, the interleaver is divided into four units (2 bits per unit) per byte and input to the trellis encoder. In this case, it can be seen that the input bits d0 and d1 are outputted as the output bits c1.c2. Bits d0 and d1 are the same since the data is passed through the repetitive encoder. Thus, the output of the trellis encoder is shown in FIG. It is displayed as one of the four symbols. In addition, since the receiver knows in advance that it has been repeatedly coded, this information can be used to improve the performance of the slicer predictor used in the channel equalizer. This information can also be used for trellis decoding.

       9 is a case where the block size of additional data is 164. In case of using the Reed-Solomon code, the data interleaver, and the repeater for the additional data shown in the above embodiment, the packet conversion until the additional data is processed and multiplexed Will show. 164 bytes of additional data are inserted into a 184 byte packet by inserting 20 bytes of parity bytes by the Reed-Solomon encoder. The number of additional parity bytes may vary depending on the number of additional data. That is, if the input additional data is 154, the parity is 30. In other words, the number of bytes of the additional data added with parity may be 184. After it is interleaved by the interleaver, it is recoded into two 184 byte packets. In addition, among the two packets divided above, the first packet does not have parity by Reed-Solomon coding and includes parity added in the second packet. Meanwhile, the MPEG header inserter inserts a 3-byte MPEG header at the beginning of the packets for compatibility with the 8T-VSB system. Finally, the multiplexer multiplexes MPEG video / acoustic data and additional data packets and transmits them through an 8T-VSB system encoding process.

     FIG. 10 illustrates a case where the block size of additional data is 82 bytes. In case of using the Reed-Solomon code, the data interleaver, and the repeater for the additional data shown in the above-described embodiment, the packet until the additional data is processed and multiplexed It shows the transformation. First, when 82 bytes of additional data is input, 10 bytes of parity are inserted by the Reed Solomon encoder and converted into 92 bytes of packet. As in FIG. 9, the number of parity can be different, i.e., if the number of additional data is 72, the parity can be 20. The additional data added with the parity is interleaved by the interleaver, and then repeatedly encoded to have 184 bytes. do. As in the case of Fig. 9, on the other hand, the MPEG header inserter inserts a 3-byte MPEG header at the beginning of the packet for compatibility with the 8T-VSB system. Finally, the multiplexer multiplexes MPEG video / audio data and additional data packets and transmits them through the encoding process of the ATSC 8T-VSB system.

As a result, the number of bytes per segment of the repeatedly encoded additional data becomes 184 and the total number of bytes added with the MPEG header is equal to 187 bytes.

As described above, the VBS communication system of the digital TV according to the present invention has an advantage of being resistant to errors and compatible with existing VSB receivers when transmitting additional data through a channel. In addition, even in a noisy channel, the additional data can be received without error.

As described above, those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

Claims (2)

Reed Solomon encoding means for encoding the additional data to be sent through the first path; Interleaving means for performing an interleaving process on the encoded additional data; Repeating encoding means for iteratively encoding the input 1 byte into 2 bytes with respect to the interleaved additional data; A header adder for adding an MPEG header to the repeated coded additional data; A multiplexer for multiplexing the additional data added with the header and MPEG data input through a second path; And a 8T-VSB transmission system for modulating and transmitting the multiplexed data with respect to the data input through the first and second paths in a VSB transmission method. delete

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